Diffractive optical element using polarization rotation grating for in-coupling

ABSTRACT

In an optical display system that includes a waveguide with multiple diffractive optical elements (DOEs), an in-coupling DOE couples light into the waveguide, an intermediate DOE provides exit pupil expansion in a first direction, and an out-coupling DOE provides exit pupil expansion in a second direction and couples light out of the waveguide. The in-coupling DOE is configured with two portions—a first portion includes a grating to rotate a polarization state of in-coupled light while a second portion couples light into the waveguide without modulation of the polarization state. The in-coupled light beams with different polarization states are combined in the waveguide after undergoing total internal reflection. However, as the difference in optical path lengths of the constituent light beams exceeds the coherence length, the combined light has random polarization (i.e., a degree of polarization equal to zero).

BACKGROUND

Diffractive optical elements (DOEs) are optical elements with a periodic structure that are commonly utilized in applications ranging from bio-technology, material processing, sensing, and testing to technical optics and optical metrology. By incorporating DOEs in an optical field of a laser or emissive display, for example, the light's “shape” can be controlled and changed flexibly according to application needs.

SUMMARY

In an optical display system that includes a waveguide with multiple diffractive optical elements (DOEs), an in-coupling DOE couples light into the waveguide, an intermediate DOE provides exit pupil expansion in a first direction, and an out-coupling DOE provides exit pupil expansion in a second direction and couples light out of the waveguide. The in-coupling DOE is configured with two portions—a first portion includes a grating to rotate a polarization state of in-coupled light while a second portion couples light into the waveguide without modulation of the polarization state. The in-coupled light beams with different polarization states are combined in the waveguide after undergoing total internal reflection. However, as the difference in optical path lengths of the constituent light beams exceeds the coherence length, the combined light has random polarization (i.e., a degree of polarization equal to zero).

The in-coupling DOE with the polarization rotating grating may provide increased display uniformity in the optical display system by reducing the “banding” resulting from optical interference that is manifested as dark stripes in the display as randomly polarized light generates weak interference. Banding may be more pronounced when polymeric materials are used in volume production of the DOEs to minimize system weight as polymeric materials may have less optimal optical properties compared with other materials such as glass. The in-coupling DOE with the polarization rotating grating can further enable the optical display system to be more tolerant to variations—such as variations in thickness, surface roughness, and grating geometry—that may not be readily controlled during manufacturing, particularly since such variations are in the submicron range. The in-coupling DOE with the polarization rotating grating can also improve in-coupling efficiency by reducing back-coupling that is caused by the reciprocity of light propagation.

This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter. Furthermore, the claimed subject matter is not limited to implementations that solve any or all disadvantages noted in any part of this disclosure.

DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a block diagram of an illustrative near eye display system which may incorporate the diffractive optical elements (DOEs) with a polarization rotation grating;

FIG. 2 shows propagation of light in a waveguide by total internal reflection;

FIG. 3 shows a view of an illustrative exit pupil expander;

FIG. 4 shows a view of the illustrative exit pupil expander in which the exit pupil is expanded along two directions;

FIG. 5 shows an illustrative arrangement of three DOEs;

FIG. 6 shows a profile of a portion of an illustrative diffraction grating that has straight gratings;

FIG. 7 shows an asymmetric profile of a portion of an illustrative diffraction grating that has slanted gratings;

FIG. 8 shows an illustrative in-coupling grating through which light is back-coupled out of a waveguide;

FIG. 9 shows an illustrative in-coupling grating having a portion that is configured to rotate a polarization state of incident light;

FIGS. 10-13 show various illustrative 2D gratings;

FIG. 14 shows an illustrative arrangement for DOE fabrication using a mask that moves relative to a substrate

FIG. 15 shows an illustrative method;

FIG. 16 is a pictorial view of an illustrative example of a virtual reality or mixed reality head mounted display (HMD) device;

FIG. 17 shows a block diagram of an illustrative example of a virtual reality or mixed reality HMD device; and

FIG. 18 shows a block diagram of an illustrative electronic device that incorporates an exit pupil expander.

Like reference numerals indicate like elements in the drawings. Elements are not drawn to scale unless otherwise indicated.

DETAILED DESCRIPTION

FIG. 1 shows a block diagram of an illustrative near eye display system 100 which may incorporate one or more diffractive optical elements (DOEs) that use a polarization rotation grating for in-coupling. Near eye display systems are frequently used, for example, in head mounted display (HMD) devices in industrial, commercial, and consumer applications. Other devices and systems may also use DOEs with polarization rotation gratings, as described below. The near eye display system 100 is intended as an example that is used to illustrate various features and aspects, and the present DOEs are not necessarily limited to near eye display systems.

System 100 may include an imager 105 that works with an optical system 110 to deliver images as a virtual display to a user's eye 115. The imager 105 may include, for example, RGB (red, green, blue) light emitting diodes (LEDs), LCOS (liquid crystal on silicon) devices, OLED (organic light emitting diode) arrays, MEMS (micro-electro mechanical system) devices, or any other suitable displays or micro-displays operating in transmission, reflection, or emission. The imager 105 may also include mirrors and other components that enable a virtual display to be composed and provide one or more input optical beams to the optical system. The optical system 110 can typically include magnifying optics 120, pupil forming optics 125, and one or more waveguides 130.

In a near eye display system the imager does not actually shine the images on a surface such as a glass lens to create the visual display for the user. This is not feasible because the human eye cannot focus on something that is that close. Indeed, rather than create a visible image on a surface, the near eye display system 100 uses the pupil forming optics 125 to form a pupil and the eye 115 acts as the last element in the optical chain and converts the light from the pupil into an image on the eye's retina as a virtual display.

The waveguide 130 facilitates light transmission between the imager and the eye. One or more waveguides can be utilized in the near eye display system because they are transparent and because they are generally small and lightweight (which is desirable in applications such as HMD devices where size and weight is generally sought to be minimized for reasons of performance and user comfort). For example, the waveguide 130 can enable the imager 105 to be located out of the way, for example, on the side of the head, leaving only a relatively small, light, and transparent waveguide optical element in front of the eyes. In one implementation, the waveguide 130 operates using a principle of total internal reflection, as shown in FIG. 2, so that light can be coupled among the various optical elements in the system 100.

FIG. 3 shows a view of an illustrative exit pupil expander (EPE) 305. EPE 305 receives an input optical beam from the imager 105 through magnifying optics 120 to produce one or more output optical beams with expanded exit pupil in one or two dimensions relative to the exit pupil of the imager (in general, the input may include more than one optical beam which may be produced by separate sources). The expanded exit pupil typically facilitates a virtual display to be sufficiently sized to meet the various design requirements of a given optical system, such as image resolution, field of view, and the like, while enabling the imager and associated components to be relatively light and compact.

The EPE 305 is configured, in this illustrative example, to support binocular operation for both the left and right eyes. Components that may be utilized for stereoscopic operation such as scanning mirrors, lenses, filters, beam splitters, MEMS devices, or the like are not shown in FIG. 3 for sake of clarity in exposition. The EPE 305 utilizes two out-coupling gratings, 310L and 310R that are supported on a waveguide 330 and a central in-coupling grating 340. The in-coupling and out-coupling gratings may be configured using multiple DOEs, as described in the illustrative example below. While the EPE 305 is depicted as having a planar configuration, other shapes may also be utilized including, for example, curved or partially spherical shapes, in which case the gratings disposed thereon would be non-co-planar.

As shown in FIG. 4, the EPE 305 may be configured to provide an expanded exit pupil in two directions (i.e., along each of a first and second coordinate axis). As shown, the exit pupil is expanded in both the vertical and horizontal directions. It may be understood that the terms “direction,” “horizontal,” and “vertical” are used primarily to establish relative orientations in the illustrative examples shown and described herein for ease of description. These terms may be intuitive for a usage scenario in which the user of the near eye display device is upright and forward facing, but less intuitive for other usage scenarios. The listed terms are not to be construed to limit the scope of the configurations (and usage scenarios therein) of DOEs with polarization rotation gratings.

FIG. 5 shows an illustrative arrangement 500 of three DOEs that may be used as part of a waveguide to provide in-coupling and expansion of the exit pupil in two directions. Each DOE is an optical element comprising a periodic structure that can modulate various properties of light in a periodic pattern such as the direction of optical axis, optical path length, and the like. The first DOE, DOE 1 (indicated by reference numeral 505), is configured to couple the beam from the imager into the waveguide. As described in more detail below, DOE 1 is configured with two parts or portions—one portion 510 provides polarization rotation to in-coupled incident light and another portion 515 provides no rotation. The second DOE, DOE 2 (520), expands the exit pupil in a first direction along a first coordinate axis, and the third DOE, DOE 3 (525), expands the exit pupil in a second direction along a second coordinate axis and couples light out of the waveguide. The angle ρ is a rotation angle between the periodic lines of DOE 2 and DOE 3 as shown. DOE 1 thus functions as an in-coupling grating and DOE 3 functions as an out-coupling grating while expanding the pupil in one direction. DOE 2 may be viewed as an intermediate grating that functions to couple light between the in-coupling and out-coupling gratings while performing exit pupil expansion in the other direction. Using such intermediate grating may eliminate a need for conventional functionalities for exit pupil expansion in an EPE such as collimating lenses.

Some near eye display system applications, such as those using HMD devices for example, can benefit by minimization of weight and bulk. As a result, the DOEs and waveguides used in an EPE may be fabricated using lightweight polymers. Such polymeric components can support design goals for size, weight, and cost, and generally facilitate manufacturability, particularly in volume production settings. However, polymeric optical elements generally have lower optical resolution relative to heavier high quality glass. Such reduced optical resolution and the waveguide's configuration to be relatively thin for weight savings and packaging constraints within a device can result in optical interference that appears as a phenomenon referred to as “banding” in the display. The optical interference that results in banding arises from light propagating within the EPE that has several paths to the same location, in which the optical path lengths differ.

The banding is generally visible in the form of dark stripes which decrease optical uniformity of the display. Their location on the display may depend on small nanometer-scale variations in the optical elements including the DOEs in one or more of thickness, surface roughness, or grating geometry including grating line width, angle, fill factor, or the like. Such variation can be difficult to characterize and manage using tools that are generally available in manufacturing environments, and particularly for volume production. Conventional solutions to reduce banding include using thicker waveguides which can add weight and complicate package design for devices and systems. Other solutions use pupil expansion in the EPE in just one direction which can result in a narrow viewing angle and heightened sensitivity to natural eye variations among users.

By comparison, when one or more of the DOEs 505, 520, and 525 (FIG. 5) are configured with gratings that have an asymmetric profile, banding can be reduced even when the DOEs are fabricated from polymers and the waveguide 130 (FIG. 1) is relatively thin. FIG. 6 shows a profile of straight (i.e., non-slanted) grating features 600 (referred to as grating bars, grating lines, or simply “gratings”), that are formed in a substrate 605. By comparison, FIG. 7 shows grating features 700 formed in a substrate 705 that have an asymmetric profile. That is, the gratings may be slanted (i.e., non-orthogonal) relative to a plane of the waveguide. In implementations where the waveguide is non-planar, then the gratings may be slanted relative to a direction of light propagation in the waveguide. Asymmetric grating profiles can also be implemented using blazed gratings, or echelette gratings, in which grooves are formed to create grating features with asymmetric triangular or sawtooth profiles.

In FIGS. 6 and 7, the grating period is represented by d, the grating height by h, bar width by c, and the filling factor by f, where f=c/d. The slanted gratings in FIG. 7 may be described by slant angles α₁ and α₂. In one exemplary embodiment, for a DOE, d=390 nm, c=d/2, h=300 nm, α₁=α₂=45 degrees, f=0.5, and the refractive index of the substrate material is approximately 1.71. In other implementations, ranges of suitable values may include d=250 nm-450 nm, h=200 nm-400 nm, f=0.3-0.0, and α₁=30-50 degrees, with refractive indices of 1.7 to 1.9. In another exemplary embodiment, DOE 2 is configured with portions that have asymmetric profiles, while DOE 1 and DOE 3 are configured with conventional symmetric profiles using straight gratings.

By slanting the gratings in one or more of the DOEs 505, 520, and 525, banding can be reduced to increase optical uniformity while enabling manufacturing tolerances for the DOEs to be less strict, as compared with using the straight grating features shown in FIG. 6 for the same level of uniformity. That is, the slanted gratings shown in FIG. 7 are more tolerant to manufacturing variations noted above than the straight gratings shown in FIG. 6, for comparable levels of optical performance (e.g., optical resolution and optical uniformity).

Optical resolution can also be increased in the EPE 305 (FIG. 3) by rotating the polarization of one part of the input pupil and combining it with a non-rotated part. To illustrate this technique, a discussion of a conventionally configured in-coupling grating is first presented. FIG. 8 shows an edge view of an illustrative conventional in-coupling grating 805 through which some amount of incident light 810 exits the waveguide 830 on the side of incidence as back-coupled light 840. The back-coupling occurs because the coupled light undergoes total internal reflection and meets the in-coupling grating 805 and is coupled out of the waveguide through reciprocal light propagation. Back-coupling can reduce the efficiency of the in-coupling grating 805 in coupling light into the optical system. In addition, the in-coupled light using the conventional in-coupling grating 805 can generate visible banding in downstream optical elements as a result of multiple optical paths to a given point in the system in which the path length differences are less than the coherence length (i.e., a propagation distance over which the light may be considered coherent).

By comparison, FIG. 9 shows an edge view of an illustrative in-coupling grating 900 that has distinct parts or portions in which a first portion 905 provides polarization rotation to incident light and a second portion 910 does not modulate the polarization of incident light. As discussed above, in-coupling grating 900 may be used in some implementations for DOE 1 in the DOE arrangement 500 shown in FIG. 5 and described in the accompanying text. As shown, an incident beam is coupled into the waveguide 930 by the first portion 905 of the in-coupling grating 900. In this example, the incident beam is a TE polarized beam 915, but incident light could alternatively be TM polarized, or be left or right hand circularly polarized. The first portion 905 of the in-coupling grating rotates the polarization of the in-coupled TE polarized beam to a TM polarized beam 920.

When the TM polarized beam 920 undergoes total internal reflection in the waveguide 930 and meets the second portion 910 of the in-coupling DOE 900 the TM polarized beam is not coupled out of the waveguide as back-coupled light because the rotated polarization limits interaction with the second portion 910 of the in-coupling grating. This can help to reduce back-coupling in the optical system and thus increase overall in-coupling efficiency.

Another incident TE polarized beam 925 is in-coupled by the second portion 910 of the in-coupling DOE 900 without modulating the polarization. In the waveguide 930, the beams 920 and 925 with different polarizations combine after undergoing total internal reflection. The combined beam 935 is unpolarized (i.e., has random polarization in which the degree of polarization is equal to zero). The randomly polarized light generates relatively weak interference in the downstream DOEs, particularly, for example, in the intermediate DOE 2 (element 520 in FIG. 5) where there are multiple optical paths to any given point and the path length differences are small (i.e., less than the coherence length).

The polarization rotating portion 905 of the in-coupling DOE 900 may be implemented using multi-dimensional gratings such as two-dimensional (2D) gratings having periodicity in two different directions. The filling ratio of the grating structure can be varied to control the degree of polarization modulation. Alternatively, other suitable technologies may also be employed for polarization rotation such as thin film polarizing filters. A 2D grating may utilize a variety of structures, contours, surface relief features and the like that are periodic in two dimensions according to the needs of a particular implementation.

For example, FIGS. 10-13 depict various illustrative 2D gratings as respectively indicated by reference numerals 1005, 1105, 1205 and 1305. The 2D gratings in the drawings are intended to be illustrative and not limiting, and it is contemplated that variations from the 2D gratings shown may also be utilized. Gratings may include symmetric and/or asymmetric features including slanted gratings (i.e., gratings having walls that are non-orthogonal according to one or more predetermined angles to a plane of the waveguide) and blazed gratings (i.e., gratings having asymmetric triangular or sawtooth profiles) in some cases. Various suitable surface relief contours/elements/features, filling factors, grating periods, and grating dimensions can also be utilized and implemented to control various optical properties and characteristics according to the needs of a particular implementation.

FIG. 10 shows a 2D grating 1005 that includes quadrangular elements that project from a substrate. The quadrangular elements can also be configured to be asymmetric such as being slanted or blazed. Non-quadrangular three-dimensional geometries (both symmetric and asymmetric) may also be utilized for a 2D grating including, for example, cylindrical elements, polygonal elements, elliptical elements, or the like. For example, FIG. 11 shows a 2D grating 1105 that includes pyramidal elements, and FIG. 12 shows a 2D grating 1205 that includes elements that have a blazed profile in each of the x and z directions. Gratings may also have elements with curved profiles, as shown in the illustrative 2D grating 1305 in FIG. 13.

FIG. 14 shows an illustrative arrangement for DOE fabrication using a mask 1405 that moves relative to a photosensitive grating substrate 1410 within an enclosure 1415. A reactive ion etching plasma 1420 is used to adjust the thickness of the etching on the grating substrate at various positions by moving the substrate relative to the mask using, for example, a computer-controller stepper functionality or other suitable control system. In an illustrative example, the etching may be performed using a reactive ion beam etching (RIBE). However, other variations of ion beam etching may be utilized in various implementations including, for example, such as magnetron reactive ion etching (MRIE), high density plasma etching (HDP), transformer coupled plasma etching (TCP), inductively coupled plasma etching (ICP), and electron resonance plasma etching (ECR). In some implementations, the substrate holder 1408 may be configured to rotate the grating substrate 1410 about an axis relative to a reactive ion etching plasma source 1420. Exposure to the plasma may be used, for example, to adjust the thickness and orientation of the etching on the grating substrate at various positions by angling the substrate relative to the source 1420.

By controlling the exposure of the substrate to the plasma through the mask aperture, grating depth can be varied as a function of position over the extent of the substrate to thereby enable various grating profiles to be incorporated on the substrate. The resulting microstructure on the substrate may be replicated for mass production in a lightweight polymer material using one of cast-and-cure, embossing, compression molding, or compression injection molding, for example.

FIG. 15 is a flowchart of an illustrative method 1500. Unless specifically stated, the methods or steps shown in the flowchart and described in the accompanying text are not constrained to a particular order or sequence. In addition, some of the methods or steps thereof can occur or be performed concurrently and not all the methods or steps have to be performed in a given implementation depending on the requirements of such implementation and some methods or steps may be optionally utilized.

In step 1505, light is received at an in-coupling DOE. The in-coupling DOE is disposed in an EPE and interfaces with the downstream intermediate DOE that is disposed in the EPE. The in-coupling DOE includes a polarization rotating portion and a portion that performs no polarization modulation. In step 1510, the exit pupil of the received light is expanded along a first coordinate axis in the intermediate DOE. In step 1515, the exit pupil is expanded in an out-coupling DOE which outputs light with an expanded exit pupil relative to the received light at the in-coupling DOE along the first and second coordinate axes in step 1520. The intermediate DOE is configured to interface with a downstream out-coupling DOE. In some implementations, the out-coupling DOE may be apodized with shallow gratings that are configured to be either straight or slanted.

DOEs with polarization rotating grating portions for in-coupling may be incorporated into a display system that is utilized in a virtual or mixed reality display device. Such device may take any suitable form, including but not limited to near eye devices such as an HMD device. A see-through display may be used in some implementations while an opaque (i.e., non-see-through) display using a camera-based pass-through or outward facing sensor, for example, may be used in other implementations.

FIG. 16 shows one particular illustrative example of a see-through, mixed reality or virtual reality display system 1600, and FIG. 17 shows a functional block diagram of the system 1600. Display system 1600 comprises one or more lenses 1602 that form a part of a see-through display subsystem 1604, such that images may be displayed using lenses 1602 (e.g. using projection onto lenses 1602, one or more waveguide systems incorporated into the lenses 1602, and/or in any other suitable manner). Display system 1600 further comprises one or more outward-facing image sensors 1606 configured to acquire images of a background scene and/or physical environment being viewed by a user, and may include one or more microphones 1608 configured to detect sounds, such as voice commands from a user. Outward-facing image sensors 1606 may include one or more depth sensors and/or one or more two-dimensional image sensors. In alternative arrangements, as noted above, a mixed reality or virtual reality display system, instead of incorporating a see-through display subsystem, may display mixed reality or virtual reality images through a viewfinder mode for an outward-facing image sensor.

The display system 1600 may further include a gaze detection subsystem 1610 configured for detecting a direction of gaze of each eye of a user or a direction or location of focus, as described above. Gaze detection subsystem 1610 may be configured to determine gaze directions of each of a user's eyes in any suitable manner. For example, in the illustrative example shown, a gaze detection subsystem 1610 includes one or more glint sources 1612, such as infrared light sources, that are configured to cause a glint of light to reflect from each eyeball of a user, and one or more image sensors 1614, such as inward-facing sensors, that are configured to capture an image of each eyeball of the user. Changes in the glints from the user's eyeballs and/or a location of a user's pupil, as determined from image data gathered using the image sensor(s) 1614, may be used to determine a direction of gaze.

In addition, a location at which gaze lines projected from the user's eyes intersect the external display may be used to determine an object at which the user is gazing (e.g. a displayed virtual object and/or real background object). Gaze detection subsystem 1610 may have any suitable number and arrangement of light sources and image sensors. In some implementations, the gaze detection subsystem 1610 may be omitted.

The display system 1600 may also include additional sensors. For example, display system 1600 may comprise a global positioning system (GPS) subsystem 1616 to allow a location of the display system 1600 to be determined. This may help to identify real world objects, such as buildings, etc. that may be located in the user's adjoining physical environment.

The display system 1600 may further include one or more motion sensors 1618 (e.g., inertial, multi-axis gyroscopic, or acceleration sensors) to detect movement and position/orientation/pose of a user's head when the user is wearing the system as part of a mixed reality or virtual reality HMD device. Motion data may be used, potentially along with eye-tracking glint data and outward-facing image data, for gaze detection, as well as for image stabilization to help correct for blur in images from the outward-facing image sensor(s) 1606. The use of motion data may allow changes in gaze location to be tracked even if image data from outward-facing image sensor(s) 1606 cannot be resolved.

In addition, motion sensors 1618, as well as microphone(s) 1608 and gaze detection subsystem 1610, also may be employed as user input devices, such that a user may interact with the display system 1600 via gestures of the eye, neck and/or head, as well as via verbal commands in some cases. It may be understood that sensors illustrated in FIGS. 16 and 17 and described in the accompanying text are included for the purpose of example and are not intended to be limiting in any manner, as any other suitable sensors and/or combination of sensors may be utilized to meet the needs of a particular implementation. For example, biometric sensors (e.g., for detecting heart and respiration rates, blood pressure, brain activity, body temperature, etc.) or environmental sensors (e.g., for detecting temperature, humidity, elevation, UV (ultraviolet) light levels, etc.) may be utilized in some implementations.

The display system 1600 can further include a controller 1620 having a logic subsystem 1622 and a data storage subsystem 1624 in communication with the sensors, gaze detection subsystem 1610, display subsystem 1604, and/or other components through a communications subsystem 1626. The communications subsystem 1626 can also facilitate the display system being operated in conjunction with remotely located resources, such as processing, storage, power, data, and services. That is, in some implementations, an HMD device can be operated as part of a system that can distribute resources and capabilities among different components and subsystems.

The storage subsystem 1624 may include instructions stored thereon that are executable by logic subsystem 1622, for example, to receive and interpret inputs from the sensors, to identify location and movements of a user, to identify real objects using surface reconstruction and other techniques, and dim/fade the display based on distance to objects so as to enable the objects to be seen by the user, among other tasks.

The display system 1600 is configured with one or more audio transducers 1628 (e.g., speakers, earphones, etc.) so that audio can be utilized as part of a mixed reality or virtual reality experience. A power management subsystem 1630 may include one or more batteries 1632 and/or protection circuit modules (PCMs) and an associated charger interface 1634 and/or remote power interface for supplying power to components in the display system 1600.

It may be appreciated that the display system 1600 is described for the purpose of example, and thus is not meant to be limiting. It is to be further understood that the display device may include additional and/or alternative sensors, cameras, microphones, input devices, output devices, etc. than those shown without departing from the scope of the present arrangement. Additionally, the physical configuration of a display device and its various sensors and subcomponents may take a variety of different forms without departing from the scope of the present arrangement.

As shown in FIG. 18, an EPE incorporating one or more DOEs with polarization rotating grating portions for in-coupling can be used in a mobile or portable electronic device 1800, such as a mobile phone, smartphone, personal digital assistant (PDA), communicator, portable Internet appliance, hand-held computer, digital video or still camera, wearable computer, computer game device, specialized bring-to-the-eye product for viewing, or other portable electronic device. As shown, the portable device 1800 includes a housing 1805 to house a communication module 1810 for receiving and transmitting information from and to an external device, or a remote system or service (not shown).

The portable device 1800 may also include an image processing module 1815 for handling the received and transmitted information, and a virtual display system 1820 to support viewing of images. The virtual display system 1820 can include a micro-display or an imager 1825 and an optical engine 1830. The image processing module 1815 may be operatively connected to the optical engine 1830 to provide image data, such as video data, to the imager 1825 to display an image thereon. An EPE 1835 using one or more DOEs with polarization rotating grating portions for in-coupling can be optically linked to an optical engine 1830.

An EPE using one or more DOEs with polarization rotating grating portions for in-coupling may also be utilized in non-portable devices, such as gaming devices, multimedia consoles, personal computers, vending machines, smart appliances, Internet-connected devices, and home appliances, such as an oven, microwave oven, and other appliances, and other non-portable devices.

Various exemplary embodiments of the present diffractive optical element using polarization rotation gratings for in-coupling are now presented by way of illustration and not as an exhaustive list of all embodiments. An example includes an optical system, comprising: a substrate of optical material; a first diffractive optical element (DOE) disposed on the substrate, the first DOE having an input surface and configured as an in-coupling grating to receive one or more optical beams as an input; and a second DOE disposed on the substrate and configured for pupil expansion of the one or more optical beams along a first direction, wherein at least a portion of the first DOE is configured with a polarization rotating grating.

In another example, the polarization rotating grating is configured as a two-dimensional grating that is periodic in two different directions. In another example, the one or more optical beams received at the first DOE emanate as a virtual image produced by a micro-display or imager. In another example, the optical system further includes a third DOE disposed on the substrate, the third DOE having an output surface and configured for pupil expansion of the one or more optical beams along a second direction, and further configured as an out-coupling grating to couple, as an output from the output surface, one or more optical beams with expanded pupil relative to the input. In another example, differences among optical path lengths in the second DOE exceed a coherence length so as to improve display uniformity in the third DOE.

A further example includes an electronic device, comprising: a data processing unit; an optical engine operatively connected to the data processing unit for receiving image data from the data processing unit; an imager operatively connected to the optical engine to form images based on the image data and to generate one or more input optical beams incorporating the images; and an exit pupil expander, responsive to the one or more input optical beams, comprising a structure on which multiple diffractive optical elements (DOEs) are disposed, in which the exit pupil expander is configured to provide one or more output optical beams, using one or more of the DOEs, as a near eye virtual display with an expanded exit pupil, and wherein at least one of the DOEs has at least one portion configured as a polarization rotating grating with a plurality of grating elements that are periodically arranged along first and second directions that are different from each other.

In another example, the at least one DOE further includes at least one other portion that is configured to perform no polarization modulation of incident light. In another example, the exit pupil expander provides pupil expansion in two directions. In another example, the imager includes one of light emitting diode, liquid crystal on silicon device, organic light emitting diode array, or micro-electro mechanical system device. In another example, the imager comprises a micro-display operating in one of transmission, reflection, or emission. In another example, the electronic device is implemented in a head mounted display device or portable electronic device. In another example, each of the one or more input optical beams is produced by a corresponding one or more sources. In another example, the structure is curved or partially spherical. In another example, two or more of the DOEs are non-co-planar.

A further example includes a method, comprising: receiving light at an in-coupling diffractive optical element (DOE) disposed in an exit pupil expander; expanding an exit pupil of the received light along a first coordinate axis in an intermediate DOE disposed in the exit pupil expander; expanding the exit pupil along a second coordinate axis in an out-coupling DOE disposed in the exit pupil expander; and outputting light with an expanded exit pupil relative to the received light at the in-coupling DOE along the first and second coordinate axes using the out-coupling DOE, in which the in-coupling DOE includes gratings configured to provide a periodic contoured surface having a first periodicity along a first direction and a second periodicity along a second direction so as to cause rotation of a polarization state of optical beams that are incident on the in-coupling DOE.

In another example, the periodic contoured surface comprises one of quadrangular elements, cylindrical elements, polygonal elements, elliptical elements, pyramidal elements, curved elements, or combinations thereof. In another example, the in-coupling DOE, the intermediate DOE, or the out-coupling DOE is formed with a polymer that is molded from a substrate that is etched using ion beam etching in which the substrate has changeable orientation relative to an ion beam source. In another example, at least a portion of the out-coupling DOE is an apodized diffraction grating having shallow grooves relative to the in-coupling DOE or the intermediate DOE. In another example, the method is performed in a near eye display system. In another example, the output light provides a virtual display to a user of the near eye display system.

Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims. 

What is claimed:
 1. An optical system, comprising: a substrate of optical material; a first diffractive optical element (DOE) disposed on the substrate, the first DOE having an input surface and configured as an in-coupling grating to receive one or more optical beams as an input; and a second DOE disposed on the substrate and configured for pupil expansion of the one or more optical beams along a first direction, wherein a first portion of the first DOE is configured with a polarization rotating grating and a second portion of the first DOE is configured without a polarization rotating grating, wherein the first and second portions are configured to combine respectively received beams to generate a combined beam.
 2. The optical system of claim 1 in which the polarization rotating grating is configured as a two-dimensional grating that is periodic in two different directions.
 3. The optical system of claim 1 in which the one or more optical beams received at the first DOE emanate as a virtual image produced by a micro-display or imager.
 4. The optical system of claim 1 further including a third DOE disposed on the substrate, the third DOE having an output surface and configured for pupil expansion of the one or more optical beams along a second direction, and further configured as an out-coupling grating to couple, as an output from the output surface, one or more optical beams with expanded pupil relative to the input.
 5. The optical system of claim 4 in which differences among optical path lengths in the second DOE exceed a coherence length so as to improve display uniformity in the third DOE.
 6. An electronic device, comprising: a data processing unit; an optical engine operatively connected to the data processing unit for receiving image data from the data processing unit; an imager operatively connected to the optical engine to form images based on the image data and to generate one or more input optical beams incorporating the images; and an exit pupil expander, responsive to the one or more input optical beams, comprising a structure on which multiple diffractive optical elements (DOEs) are disposed, in which the exit pupil expander is configured to provide one or more output optical beams, using one or more of the DOEs, as a near eye virtual display with an expanded exit pupil, wherein at least one of the DOEs has one portion configured as a polarization rotating grating with a plurality of grating elements that are periodically arranged along first and second directions that are different from each other, in which the at least one DOE further includes at least one other portion that is configured to perform no polarization modulation of the optical beams, and in which both portions are configured to combine respectively received optical beams to generate a combined beam.
 7. The electronic device of claim 6 in which the exit pupil expander provides pupil expansion in two directions.
 8. The electronic device of claim 6 in which the imager includes one of light emitting diode, liquid crystal on silicon device, organic light emitting diode array, or micro-electro mechanical system device.
 9. The electronic device of claim 6 in which the imager comprises a micro-display operating in one of transmission, reflection, or emission.
 10. The electronic device of claim 6 as implemented in a head mounted display device or portable electronic device.
 11. The electronic device of claim 6 in which each of the one or more input optical beams is produced by a corresponding one or more sources.
 12. The electronic device of claim 6 in which the structure is curved or partially spherical.
 13. The electronic device of claim 6 in which two or more of the DOEs are non-co-planar.
 14. A method, comprising: receiving light at an in-coupling diffractive optical element (DOE) disposed in an exit pupil expander; expanding an exit pupil of the received light along a first coordinate axis in an intermediate DOE disposed in the exit pupil expander; expanding the exit pupil along a second coordinate axis in an out-coupling DOE disposed in the exit pupil expander; and outputting light with an expanded exit pupil relative to the received light at the in-coupling DOE along the first and second coordinate axes using the out-coupling DOE, in which the in-coupling DOE includes a first portion with gratings configured to provide a periodic contoured surface having a first periodicity along a first direction and a second periodicity along a second direction so as to cause rotation of a polarization state of optical beams that are incident on the in-coupling DOE, and in which the in-coupling DOE includes a second portion with gratings configured not to cause rotation of a polarization state of optical beams incident on the in-coupling DOE, wherein the first and second portions are configured to combine respectively received optical beams to generate a combined beam.
 15. The method of claim 14 in which the periodic contoured surface comprises one of quadrangular elements, cylindrical elements, polygonal elements, elliptical elements, pyramidal elements, curved elements, or combinations thereof.
 16. The method of claim 14 in which the in-coupling DOE, the intermediate DOE, or the out-coupling DOE is formed with a polymer that is molded from a substrate that is etched using ion beam etching in which the substrate has changeable orientation relative to an ion beam source.
 17. The method of claim 14 further in which at least a portion of the out-coupling DOE is an apodized diffraction grating having shallow grooves relative to the in-coupling DOE or the intermediate DOE.
 18. The method of claim 14 as performed in a near eye display system.
 19. The method of claim 18 in which the output light provides a virtual display to a user of the near eye display system. 